A moon of mass m and radius a is orbiting a planet of mass M and of radius b at a distance d (center-to-center) in a circular orbit. Derive an expression for the total mechanical energy E of the moon in terms of m, M, d and the gravitational constant G.

A moon of mass m and radius a is orbiting a planet of mass M and of radius b at a distance d (center-to-center) in a circular orbit. Derive an expression for the total mechanical energy E of the moon in terms of m, M, d and the gravitational constant G.

Name: A moon of mass m and radius a is orbiting a planet of mass M and of ra
Uploaded: 2024-03-20T06:57:16.000Z
Channel: Bartleby
Description: A moon of mass m and radius a is orbiting a planet of mass M and of radius b at a distance d (center-to-center) in a circular orbit. Derive an expression for the total mechanical energy E of the moon in terms of m, M, d and the gravitational constant

Physics for Scientists and Engineers: Foundations and Connections

1st Edition

ISBN:9781133939146

Author:Katz, Debora M.

Publisher:Katz, Debora M.

Chapter8: Conservation Of Energy

Section: Chapter Questions

Problem 73PQ

See similar textbooks

Related questions

Q: In the figure, a small block of mass m = 0.024 kg can slide along the frictionless loop-the-loop,…

Q: Gravitational attraction force between two objects with masses m1 and m2, separated by distance x,…

Q: A spacecraft of mass m moves around Earth in a circular orbit with a constant radius r at constant…

A: Given data: Mass of spacecraft is, m. Radius of circular orbit is, r.

Q: The potential energy is dependent with height h from the surface of the earth while the kinetic…

A: The mathematical expression of potential energy is : PE = mgh Here, m is the mass of the object, g…

Q: A 475 kg satellite is in a circular orbit at an altitude of 600 km above the Earth's surface.…

Q: A 5 kg book is held 10 meters above the floor. How much gravitational potential energy does it have?…

A: Mass(m) = 5 kg Height(h) = 10 m Potential energy (E) = mgh g = gravitational acceleration g = 9.8…

Q: A satelite is in geostationary orbit. How much energy is required to move it to a circular orbit…

A: Given Period of new orbit T' = 8 days Known Values Geo stationary orbit radius r = 4.2 x 107 m the…

Q: In the figure, a small block of mass m = 0.049 kg can slide along the frictionless loop-the-loop,…

A: In this question we have to find the work done and the potential energy. Please give positive…

Q: Which explanation most thoroughly describes the relationship between factor(s) and potential energy?…

A: we can see that the greatest potential energy is at a height 2m and the mass is 6kg. In this case,…

Q: In the figure, a small block of mass m = 0.024 kg can slide along the frictionless loop-the-loop,…

A: Given,Mass of the small block, , = 0.024radius of the loop, R = 15 cmThe block is released form rest…

Q: Consider a uniform rod of mass 30 kg and length 1.7 m. The rod is pinned at one end and allowed to…

A: SOution: Givent that Mass = M=30 kg Length =l = 1.7 m Angle = θ = 44 degree

Q: as the vertical distance of the The potential energy of an object same object from the surface of…

Q: If the gravitational potential energy of 5 Kg rock is 980 J. How high is the rock above the ground?…

A: Given: The mass of the rock is m=5 kg. The gravitational potential energy of rock is E=980 J.…

Q: Derive an algebraic expression that gives the launch velocity for any object to reach a very great…

Q: Consider the gravitational potential energy of two configurations: the first, when Mars and Earth…

Q: Base your answer(s) to the following question(s) on the graph below, which represents the…

Q: An astronaut working on the Moon tries to determine the gravitational constant G by throwing a Moon…

A: a) Write the expression for the gravitational potential energy at a distance r. Here, G represents…

Q: The following table of elevations and energy levels correspond to an NBA basketball travelling…

A: Given data: Mass (m) = 0.600 kg Height (h) = 5.00 m Required: Gravitational Potential Energy (GPE)

Q: Earth exerts a gravitational force (F.) on the moon and so the moon moves in a nearly circular orbit…

A: The gravitational force is an attractive force. Two objects in the universe attract each other with…

Q: An astronaut working on the Moon tries to determine the gravitational constant G by throwing a Moon…

A: Given: Moon density ρ = 3340 kgm3 Radius R = 1740 km. (a) Gravitational potential energy: E=-GMmR…

Q: A 415kg satellite orbiting the earth experiences 215N of gravitational force from the Earth.…

A: Ms = 415 kg F = 215 N RE = 6.38 x 106 m ME = 5.97 x 1024 kg H = ? U = ? 6.673×10−11N

Q: Earth exerts a gravitational force (F.) on the moon and so the moon moves in a nearly circular orbit…

Q: A mass m placed at a height h from the ground has a gravitational potential energy PE, (with respect…

Q: Zero, a hypothetical planet, has a mass of 5.0 * 102^3 kg, a radius of 3.0 * 10^6 m, and no…

Q: A ball of mass 0.500 kg is carefully balanced on a shelf that is 3.00 m above the ground. What is…

Q: What is the gravitational potential energy of a 50 N bird at a height of 50 meters? A. 2500 J…

A: Given Data : The weight of the bird is given as W = 50N. The height of the bird is given as H = 50m.

Q: Derive an expression for the work required to move an Earth satellite of mass m from a circular…

Q: Consider a popup foul baseball, that is in a state of in “free fall” fall back to the ground. As the…

Q: In the figure, a small block of mass m = 0.047 kg can slide along the frictionless loop-the-loop,…

A: (a)Find the work done by the gravitational force on the block to move from the point P to Q.

Q: In the figure, a small block of mass m = 0.032 kg can slide along the frictionless loop- the-loop,…

A: Introduction: When body released from a certain height H, its potential energy goes on decreasing…

Q: In the figure, a small block of mass m = 0.034 kg can slide along the frictionless loop-the-loop,…

Q: How much gravitational potential energy (relative to the ground on which it is built) is stored in…

A: Given: The mass of the pyramid is 9x109 kg. The height of the center of mass of the pyramid is 42 m…

Q: Compute the work done by the force F(x, y) = (x²–y)i+xjacting on an insect as it moves along a…

Q: For a satellite orbiting the earth, the distance D from the center of the Earth is a power function…

A: The relation between the distance from the center of the Earth and the period of the satellite is…

Q: The amount of potential energy, P, an object has is What is the equivalent equation solved for h?…

A: The gravitational potential energy of the object at a height is, P = mgh Where, P = potential energy…

Q: A rock of 3.2 kg is lifted to a height of 6.7 m from the surface of the planet. The work done is 60…

A: In the given question, Work done (W) is 60 J when the rock of mass 3.2kg is lifted to a height of…

Q: A gravitational potential energy function of a particle is U(y) = (2.00y2 + 3.00y + 6.00) J.…

A: Given: U(y)=(2.00y2+3.00y+6.00)J To find: Gravitational force at displacement 1.0 m = F at y=1.0 m…

Q: In the figure, a small block of mass m = 0.015 kg can slide along the frictionless loop-the-loop,…

Q: What is the gravitational potential energy of a 230 g bird flying 1 km off the surface of the earth?

Q: The figure shows four particles, each of mass 17.5 g, that form a square with an edge length of d =…

Q: kg stone is dropped into a water well while being held 1.2 m above the top of the well's rim. There…

A: We know that we have given that the mass of the stone is m = 0.32 kg The stone dropped into the…

Q: Two skiers, with masses of 72 kg and 58 kg, are at the top of a ski hill. The altitude at the top of…

A: Given data: Masses of skiers m1 = 72 kg and m2 = 58 kg Height of top of hill = 3782 m Height of ski…

Q: onsider the mechanical energy of a body in geostationary orbit above the Earth's equator, at…

A: Given:- Consider the mechanical energy of a body in geostationary orbit above the Earth's equator,…

Q: lunar module weighs 12 metric tons on the surface of the Earth. How much work is done in propelling…

A: Given: h=80 miles Force of gravity on the surface of earth =12 metric tons. mgearth=16mgmoon…

Q: A block of mass m is placed on a rough incline surface making an angle 0 = 28.3 with horizontal. A…

Q: a. Planet Alpha has a mass of 2.34 x 1025 kg and a radius of 5.67 × 107 m. What is the gravitational…

A: Given data: Mass of the planet Alpha m=2.34×1025 kg Radius r =5.67×107 m

Q: In the figure, a small block of mass m = 0.014 kg can slide along the frictionless loop-the-loop,…

Concept explainers

Kinematics

A machine is a device that accepts energy in some available form and utilizes it to do a type of work. Energy, work, or power has to be transferred from one mechanical part to another to run a machine. While the transfer of energy between two machine parts, those two parts experience a relative motion with each other. Studying such relative motions is termed kinematics.

Kinetic Energy and Work-Energy Theorem

In physics, work is the product of the net force in direction of the displacement and the magnitude of this displacement or it can also be defined as the energy transfer of an object when it is moved for a distance due to the forces acting on it in the direction of displacement and perpendicular to the displacement which is called the normal force. Energy is the capacity of any object doing work. The SI unit of work is joule and energy is Joule. This principle follows the second law of Newton's law of motion where the net force causes the acceleration of an object. The force of gravity which is downward force and the normal force acting on an object which is perpendicular to the object are equal in magnitude but opposite to the direction, so while determining the net force, these two components cancel out. The net force is the horizontal component of the force and in our explanation, we consider everything as frictionless surface since friction should also be calculated while called the work-energy component of the object. The two most basics of energy classification are potential energy and kinetic energy. There are various kinds of kinetic energy like chemical, mechanical, thermal, nuclear, electrical, radiant energy, and so on. The work is done when there is a change in energy and it mainly depends on the application of force and movement of the object. Let us say how much work is needed to lift a 5kg ball 5m high. Work is mathematically represented as Force ×Displacement. So it will be 5kg times the gravitational constant on earth and the distance moved by the object. Wnet=Fnet times Displacement. 

Topic Video

Question

A moon of mass m and radius a is orbiting a planet of mass M and of radius b at a distance d (center-to-center) in a circular orbit.

Derive an expression for the total mechanical energy E of the moon in terms of m, M, d and the gravitational constant G.

Expert Solution

This question has been solved!

Explore an expertly crafted, step-by-step solution for a thorough understanding of key concepts.

This is a popular solution!

SEE SOLUTION Check out a sample Q&A here

Step 1

Step 2

Step 3

Step 4

Step 5

Step 6

Step 7

Step 8

Trending now

This is a popular solution!

Step by step

Solved in 8 steps with 7 images

SEE SOLUTION Check out a sample Q&A here

Knowledge Booster

Learn more about

Need a deep-dive on the concept behind this application? Look no further. Learn more about this topic, physics and related others by exploring similar questions and additional content below.

Similar questions

A system consists of five particles. How many terms appear in the expression for the total gravitational potential energy of the system? (a) 4 (b) 5 (c) 10 (d) 20 (e) 25
Rank the following quantities of energy from largest to the smallest. State if any are equal. (a) the absolute value of the average potential energy of the SunEarth system (b) the average kinetic energy of the Earth in its orbital motion relative to the Sun (c) the absolute value of the total energy of the SunEarth system
A mysterious force acts on all particles along a particular line and always points towards a particular point P on the line. The magnitude of the force on a particle increases as the cube of the distance from that point; that is Fr3 , if the distance from P to the position of the particle is r. Let b be the proportionality constant, and write the magnitude of the force as F=br3. Find the potential energy of a particle subjected to this force when the particle is at a distance D from P, assuming the potential energy to be zero when the particle is at P.
In each situation shown in Figure P8.12, a ball moves from point A to point B. Use the following data to find the change in the gravitational potential energy in each case. You can assume that the radius of the ball is negligible. a. h = 1.35 m, = 25, and m = 0.65 kg b. R = 33.5 m and m = 756 kg c. R = 33.5 m and m = 756 kg FIGURE P8.12 Problems 12, 13, and 14.
A block of mass 200 g is attached at the end of a massless spring of spring constant 50 N/m. The other end of the spring is attached to the ceiling and the mass is released at a height considered to be where the gravitational potential energy is zero. (a) What is the net potential energy of the block at the instant the block is at the lowest point? (b) What is the net potential energy of the block at the midpoint of its descent? (c) What is the speed of the block at the midpoint of its descent?
(a) What is the change in energy of a 1000-kg payload taken from rest at the surface of Earth and placed at rest on the surface of the Moon? (b) What would be the answer if the payload were taken from the Moon’s surface to Earth? Is this a reasonable calculation of the energy needed to move a payload back and forth?
The magnitude of the gravitational force between a particle of mass m₁ and one of mass m2 is given by F(x) = G m1m2 x2 where G is a constant and x is the distance between the particles. NOTE: Express your answers in terms of the variables given. (a) What is the corresponding potential energy function U(x)? Assume that U(x) → 0 as x → ∞ and that x is positive. U(x) = (b) How much work is required to increase the separation of the particles from x = x₁ to x = x1+d? W =
A satellite in Earth orbit has a mass of 96 kg and is at an altitude of 1.98 x 10° m. (Assume that U = 0 as r – ∞.) (a) What is the potential energy of the satellite-Earth system? (b) What is the magnitude of the gravitational force exerted by the Earth on the satellite? 97671.15 What is the equation for gravitational force when the altitude is comparable to the radius of the Earth? N (c) What force, if any, does the satellite exert on the Earth? (Enter the magnitude of the force, if there is no force enter 0.)
Ten days after it was launched toward Mars in December 1998, the Mars Climate Orbiter spacecraft (mass 629 kg) was 2.87 * 10^6 km from the earth and traveling at 1.20 * 10^4 km/h relative to the earth. At this time, what were (a) the spacecraft’s kinetic energy relative to the earth and (b) the potential energy of the earth–spacecraft system?
A child of mass m = 29 kg slides down a slide of height h = 2.4 m without friction. Let gravitational potential energy be zero at ground level. Part A : Write an expression for the child's total mechanical energy, E, at the top of the slide, in terms of the variables in the problem and the acceleration due to gravity g. Part B : Calculate the change in the child's potential energy, ΔU in joules, from the top to the bottom of the slide at ground level (i.e. ΔU = Uground - Utop). Part C: What is the child's final speed, vf in m/s?
Identical satellites X and Y of mass m are in circular orbits around a planet of mass M. The radius of the planet is R. Satellite X has an orbital radius of 3R, and satellite Y has an orbital radius of 4R. The kinetic energy of satellite X is KX. Satellite X is moved to the same orbit as satellite Y by a force doing work on the satellite. In terms of KX , the work done on satellite X by the force is
An 8000 kg satellite is launched from the surface of the Earth into outer space. What initial kinetic energy is needed by the satellite in order to reach a great (i.e., infinite) distance from the Earth, neglecting the effects of air resistance in the atmosphere? (G = 6.67 × 10−11 N·m2/kg2, ME = 5.97 × 1024 kg, RE = 6.37 × 106 m.)